A device includes a handle, an apparatus for probing and cutting, and an adaptor. The handle includes one or more triggers. The apparatus for probing and cutting is connectable to the handle and includes an elongated member, a probe, and a blade. The probe and the blade are selectively deployable from the elongate member via activation of the one or more triggers on the handle. The adaptor is configured to selectively connect the apparatus to the handle in a predetermined orientation.
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1. A device comprising:
a handle with one or more triggers;
an apparatus for probing and cutting connectable to the handle, the apparatus comprising an elongated member, a probe, and a blade, the probe and the blade being selectively deployable from the elongate member via activation of the one or more triggers on the handle, the probe being mounted on a pivot pin and configured to pivot on the pivot pin between an undeployed state and a deployed state, the blade being moveable from an undeployed state to an extended state, the blade being configured to interface with the pivot pin to (i) guide the movement of the blade form the undeployed state to the extended state and/or (ii) limit the movement of the blade towards the deployed state; and
an adaptor configured to selectively connect the apparatus to the handle in a predetermined orientation.
14. An apparatus for probing and cutting, comprising:
an elongate member having a proximal end and a distal end;
a probe rotatably mounted to the elongate member near the distal end thereof, the probe being selectively movable between an undeployed state and a probing state via pivoting about a pivot pin, the probe comprising a target acquisition surface that: (i) is disposed within the elongate member and extends at least partially towards the distal end thereof when the probe is in the undeployed state, and (ii) extends at least partially from the elongate member and is closer to the proximal end of the elongate member when the probe is in the probing state; and
a blade slidably and pivotally mounted to the elongate member such that the blade moves linearly in a direction generally parallel to a longitudinal axis of the elongate member and pivots about a pivot point as the blade moves between an undeployed state and an extended state, the blade comprising a linear slot extending therethrough and configured to receive a blade pivot pin therein.
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This application is a continuation in part of U.S. patent application Ser. No. 15/399,425, filed Jan. 5, 2017, and APPARATUS WITH DEPLOYABLE PROBE AND BLADE AND METHODS OF USE. This application is also a continuation in part of International Patent Application No. PCT/US2018/012354, filed Jan. 4, 2018, and entitled APPARATUS WITH DEPLOYABLE PROBE AND BLADE AND METHODS OF USE, which claims priority to U.S. Provisional Patent Application No. 62/506,924, filed May 16, 2017, and entitled APPARATUS WITH DEPLOYABLE PROBE AND BLADE AND METHODS OF USE, and to U.S. patent application Ser. No. 15/399,425, filed Jan. 5, 2017, and entitled APPARATUS WITH DEPLOYABLE PROBE AND BLADE AND METHODS OF USE. The foregoing applications are incorporated herein by reference in their entirety.
This disclosure generally relates to apparatuses for probing and cutting and associated methods of use. More specifically, the present disclosure relates to apparatuses comprising a deployable probe for locating a target to be cut and a deployable blade for cutting said target and associated methods of using said apparatuses.
Tools for cutting include, for example, knives, scissors, and the like. Often, a general cutting tool, such as a pair of scissors, is adapted for a particular purpose without departing from its essential design. For example, a child may use a pair of plastic scissors to cut construction paper or a chef may use a pair of kitchen shears to cut herbs or break down poultry. In both instances, the basic concept of pivotally joined blades whose cutting edges are opposed, yet complementary, is used as the foundational concept from which each tool is individually fashioned. Although a variety of context-specific tools—whether scissors, knives, or other cutting tools—can be generated according to the foregoing concept, the resultant cutting devices are generally linked by the common thread of requiring the user to see what she is cutting to accurately, knowingly, and/or specifically cut a target object.
However, direct access—whether visual or physical—to some target objects may be limited. Absent removing physical obstructions to allow for direct line of sight, there are few options available to enable a user to accurately, knowingly, and/or specifically cut an object obstructed from view. Particularly, handheld devices for locating and specifically cutting a target object are lacking.
Accordingly, there are a number of disadvantages with cutting instruments that can be addressed.
Embodiments of the present disclosure solve one or more of the foregoing or other problems in the art of handheld apparatuses for probing and cutting specific targets. An exemplary handheld apparatus for probing and cutting can include an elongate member with a first end associated with a probe and a blade. The probe can include a target interaction surface and can be selectively movable between a retracted state, a probing state, and a target acquisition state. The blade can include a cutting edge and can be selectively movable between a retracted position and an extended position.
Apparatuses for probing and cutting as disclosed herein can also include a handle associated with the second end of the elongate member. The handle can include a first manually operated control operably connected to the probe and configured to move the probe between the probing state and the target acquisition state when the first manually operated control is engaged and/or disengaged. The handle can also include a second manually operated control operably connected to the blade. The second manually operated control can be configured to move the blade between the extended position and the retracted position when the second manually operated control is engaged and/or disengaged.
Apparatuses for probing and cutting, as disclosed herein, can be used in various ways and may have particular applications, for example, as surgical tools within a surgical system for performing carpal tunnel release surgery. Additional features and advantages of the disclosure will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the disclosure. The features and advantages of the disclosure may be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. These and other features of the present disclosure will become more fully apparent from the following description and appended claims, or may be learned by the practice of the disclosure as set forth hereinafter.
In order to describe the manner in which the above recited and other advantages and features of the disclosure can be obtained, a more particular description of the disclosure briefly described above will be rendered by reference to specific embodiments thereof, which are illustrated in the appended drawings. It is appreciated that these drawings depict only typical embodiments of the disclosure and are not therefore to be considered to be limiting of its scope. The disclosure will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
Overview of Surgical Cutting Tools and Methods of Use
In general, surgical procedures are performed to treat pathological diseases (e.g., appendectomy, lobectomy of a cancerous lung, etc.), help improve bodily function or appearance (e.g., plastic or reconstructive surgery), or otherwise repair the body (e.g., repair a ruptured organ or serious injury). A plethora of surgical procedures have been created and modified over the years and employ a wide variety of surgical tools and surgical methods. Historically, most surgical procedures fell into the category of “open surgery,” which involves the surgeon making a long incision in the patient's body through which surgical instruments are introduced and also through which the surgeon visualizes the surgery. This type of surgery is particularly invasive and generally requires long healing time and extended hospital stays, but it is also associated with an increased risk of infection, likely due to the surgical site—which is normally closed off from the environment—being open and exposed to the elements and any associated infectious agents.
Recently, advances in imaging technologies, electronics, and robotics have provided surgeons with minimally invasive surgical options to replace or complement open surgery. For example, endoscopes—a type of medical device having a light and a camera—are widely used in minimally invasive surgical procedures to provide the surgeon with a view of the surgical site via the endoscopic camera. The endoscope is introduced to the surgical site through a small incision, and the endoscopic light illuminates the surgical site while the endoscopic camera transmits a real-time (or near real-time) display of the surgical site to a monitor in the surgical theatre. Sometimes a second small incision is made near the surgical site through which surgical instruments are introduced, but a single incision may be used to introduce both the endoscope and the surgical instruments. The surgeon may then perform the surgery, viewing the surgical site on the monitor as opposed to through the open surgical site as would be done in an open surgery approach.
In many instances, endoscopic surgeries are beneficial over open surgery procedures because they allow for small incisions instead of a larger incision. The small incisions may decrease the healing time, and may reduce the length of hospital stay. There also tends to be a decreased risk for infection for endoscopic surgeries.
Endoscopes are not the only medium by which image-guided surgery may be performed. Additional options include, as non-limiting examples, the use of ultrasound systems, computed tomography scanners, magnetic resonance imaging scanners, and the like. Each of these have their own particular set of drawbacks. Some of the foregoing imaging devices require the patient to be administered a contrast dye, which can, in some circumstances, cause an allergic reaction, and which are typically expensive. Additionally, magnetic resonance imaging scanners and computed tomography scanners are expensive and require specially-trained technicians to operate the device. In general, each of the aforementioned image-guided surgical devices add an additional layer of expense to the patient, and in some cases, the use of these devices is redundant or altogether unnecessary.
As a particular example comparing and contrasting open surgery and minimally invasive surgical tools and techniques, carpal tunnel release surgery involves the incision of the transverse carpal ligament (TCL) and may be performed using either an open surgery approach or endoscopically. In an open surgery approach, the physician—typically a surgeon—makes an incision in the skin, subcutaneous tissue, and palmar fascia of the patient's palm to directly access and cut the TCL. This procedure is relatively invasive and requires cutting multiple tissues to complete the surgery, and because the incised tissue is located on the patient's palm, the surgery can result in a drawn out and painful recovery.
Alternatively, carpal tunnel release surgery may be performed as a minimally invasive surgery using an endoscope. The endoscope is introduced at the patient's wrist and moved to the surgical site at which time a specialized cutting tool is either introduced at the same site as the endoscope or at a second point located on the palm. In either case, the endoscope is used to visualize the TCL, and the cutting tool is used to cut the TCL from underneath. This type of surgery typically results in faster patient recovery when compared to the open surgical approach.
Handheld Apparatuses for Probing and Cutting and Methods of Use
In one or more embodiments of the present disclosure, a handheld apparatus is disclosed that can be adapted for use as a surgical tool, and which can be used in, for example, carpal tunnel release surgery. In such embodiments, the surgical tool comprises a probe pivotally connected to a first end of an elongate member (see, for example,
Such exemplary surgical tools may be used to transect anatomic structures and may particularly be used to perform carpal tunnel release surgery with or without the assistance of image-guided surgical tools. In one or more implementations, a surgical tool as described herein is introduced to a surgical site (e.g., the wrist) and the probe is advanced and activated (i.e., advanced from a retracted state to a probing state). The activated probe pivots away from the elongate member, pressing against the ribbed or underside surface of the TCL. Upon extending the probe past the TCL, the probe pivots to a target acquisition state, whereby the probe is withdrawn until the distal margin of the TCL is acquired by the probe. The blade may then be moved into the extended position such that translocation of the surgical tool toward and/or across the TCL results in the cutting edge of the blade severing the TCL.
In one or more implementations, a surgical tool is provided that is substantially similar to that described above. However, in one or more implementations, the probe does not pivot (see, for example,
Referring now to the figures,
The apparatus 100 of
In a retracted state as depicted in
Referring now to
Referring now to
In one or more embodiments, the target acquisition state of probe 104 places the target interaction surface 110 away from elongate member 102. For example, a probe may have an arcuate shape such that it is contoured with a convex side and a concave side, and the target interaction surface of the probe comprises at least a portion of the surface of the concave side of the probe. In a probing state (such as in
Additionally, or alternatively, the partially deployed state of an apparatus for probing and cutting may include a probe in a retracted state and a blade in an extended position. This state may also be considered within the scope of a partially deployed state and is exemplary of one or more embodiments where the probe and the blade are independently movable with respect to each other. Though independently movable with respect to each other, the probe and the blade may nonetheless be connected or otherwise associated. For example, the probe and blade may be connected by one or more rods, pins, or similar mechanism known in the art that allows each of the probe and the blade to independently move with respect to the other but also provides a connection between the two components. Further, the probe and blade may be associated with each other in a retracted state and retracted position, respectively, or in a target acquisition state and an extended position, respectively, even though they are independently movable with respect to each other. Alternatively, the probe and blade may not be connected or otherwise directly associated when the disclosed apparatus is in a partially deployed state.
In one or more embodiments, the probe is pivotally joined and/or associated with the elongate member, and transitioning between the retracted state to the target acquisition state involves the probe rotating between states. The rotation and/or pivotal association of the probe with the elongate member may be accomplished by any means known in the art, including, for example, providing torsional energy through the use of a spring or other similar object that stores mechanical energy when twisted, as known in the art, or through the use of one or more elastic materials that are attached to a pivot point on the probe such that when the one or more elastic materials are stretched (e.g., by pulling) a rotation of the probe is induced about an axis.
In one or more embodiments, the probe may not rotate between a retracted state and a target acquisition state, but rather may move by any means known in the art, including, for example, by sliding between the two states.
In one or more embodiments, the probe and the blade may be directly and/or indirectly associated such that movement of one results in movement of the other. In such embodiments, the partially deployed state may not be defined with respect to the juxtaposition of the two states and/or positions of the blade and probe as described above. Instead, the partially deployed state may describe a transition state of the blade from a retracted position to an extended position and the probe from a retracted state to a target acquisition state, or it may describe the transition state between an undeployed state and a fully deployed state. Stated another way, a partially deployed state includes any combination of probe states and blade positions that are not the undeployed state described in
For example, in an embodiment where the probe and the blade are directly associated and/or or move dependently with respect to each other, a partially deployed state may comprise the blade transitioning between the retracted position and the fully extended position and the probe being released from a retracted state but not completely transitioned to the target acquisition state. The blade may be motivated from one position to another by push rod 115. In some embodiments, the probe and blade move dependently with respect to each other, and motivation of the blade by push rod 115 may consequently cause the movement of the probe between states (e.g., between a retracted state, a probing state, and/or a target acquisition state).
As provided above, the probing state may, in some embodiments, represent a transition state and/or intermediate state between the retracted state and the target acquisition state. Accordingly, the partially deployed state may comprise an apparatus having a blade in a retracted position and the probe in the probing state. A probe in the probing state may, therefore, vacillate between the retracted state and the target acquisition state without permanently and/or fully entering either the retracted state or the target acquisition state.
Referring now to
Though depicted as unobstructed in
Referring now to
As illustrated by
As illustrated in
Additionally, or alternatively, a probe may comprise a singular body, whether arcuate or not, that defines a recess for receiving and/or associating with at least a portion of a blade in an extended or retracted position as described above. The probe may, in some embodiments, occlude one or more parts of the blade and/or may direct a target over its surface to the recess with the blade therein so the blade may transect the target.
Illustrated in
Likewise,
Referring now to
In one or more embodiments, the first trigger 214 and the second trigger 216 may be any manually operated control known in the art, including, for example, a dial, switch, slider, button, lever, or combinations thereof. The manually operated control(s) associated with the handle, being in operable connection with the probe and/or blade (e.g., via a push rod such as push rod 115 of
In the embodiments depicted by
In one or more embodiments of the present disclosure, first trigger 214 is operably connected to probe 204. First trigger 214 may, in some embodiments, be in operable connection with probe 204 such that engagement (e.g., depression, extension, or the like) of first trigger 214 selectively moves the probe from a retracted state to the probing state, and to the target acquisition state. In one embodiment, depression of the first trigger causes probe 204 to be released from a retracted state to enter the probing state. Continued and/or increased depression of first trigger 214 may cause probe 204 to proceed to a target acquisition state by any means previously described. As a non-limiting example, probe 204 may be at least partially associated with elongate member 202 in a retracted state, and in response to a minor depression of first trigger 214, probe 204 may partially rotate away from elongate member 202 proportionally to the amount of pressure and/or the degree of depression received and/or experienced by first trigger 214. Continued and/or increased depression of first trigger 214 provides a proportional rotational movement of probe 204 within the probing state towards the target acquisition state. In one or more embodiments, the length of the first trigger movement is directly proportional to the rotational distance between a retracted state and a target acquisition state of the probe. In one or more embodiments, the length of the trigger movement is greater or less than the rotational distance between a retracted state and a target acquisition state of the probe.
As an additional example, the triggers may have one or multiple thresholds such that upon exceeding a first threshold, the associated probe advances a predefined distance or is advanced between states. In some embodiments, the trigger may have two thresholds, a first to move the probe from a retracted state to a probing state and a second to move the probe from a probing state to a target acquisition state. Additionally, or alternatively, a trigger may have two thresholds, a first to move the probe from a retracted state to a probing/target acquisition state and a second to move the blade from a retracted position to an extended/cutting position. In some embodiments, the thresholds may be one or more mechanical thresholds or may, additionally, or alternatively, be a tactile sensation provided through one or more members of the apparatus (e.g., through the one or more triggers, the handle, and/or the gripping region).
In one or more embodiments of the present disclosure, second trigger 216 is operably connected to blade 206 in any analogous way described above with respect to first trigger 214 and probe 204. For example, depression of second trigger 216 causes a proportional advancement of blade 206 from a retracted position to an extended position.
In one or more embodiments, releasing a depressed first trigger 214 and/or second trigger 216 causes the operably connected component to return to an original position (e.g., the retracted state for the probe and the retracted position for the blade). The foregoing may be accomplished in the same proportional manner—but in reverse—as described above when depressing the first and/or second triggers 214, 216, or in some embodiments, releasing the first trigger 214 and/or the second trigger 216 to any degree—or to a threshold degree such as, for example, halfway—causes the operably connected element to immediately and fully return to the original position.
In one or more embodiments, the triggers are binary, and move one or both of the probe and blade from a retracted state/retracted position to a target acquisition state/extended position, respectively. In one embodiment, activation of a binary trigger may release the probe from a retracted state to a probing state, which automatically proceeds to a target acquisition state when the freedom of movement allows for such transition. As a particular example, an activated trigger may move the probe from the retracted state to the probing state, at which time the probe bumps up against the TCL, and upon reaching the distal margin of the TCL (and extending far enough past to allow the probe to fully extend to a target acquisition state), the probe automatically transitions from the probing state to the target acquisition state.
The handle may further comprise a tapered region 208 that comprises a larger diameter region connected to the elongate member 202. In some embodiments, the tapered region 208 may allow a user additional leverage or stability when handling apparatus 200. Tapered region 208 may additionally, or alternatively, provide structural support to elongate member 202 and associated handle 208.
In one or more embodiments of the present disclosure, apparatuses 100, 200 may be sized and shaped for use in minimally invasive surgical procedures. Apparatuses, therefore, may be introduced via any method known in the art, including without limitation via a percutaneous procedure or via a portal opened by incision. An introducer sheath or other surgical device may be employed with apparatuses disclosed herein to assist in and/or complement introduction of the apparatus into the surgical site.
In one or more embodiments of the present disclosure, handle 208 may additionally comprise manually operated control 220 (depicted in
Also depicted in
The apparatus referred to herein may comprise a handheld apparatus for probing and cutting. More preferably, the apparatus comprises a medical device for locating and transecting target anatomical structures. In such embodiments, an analogous probe to those described herein is selectively movable between a retracted state and a target acquisition state and an analogous blade is selectively movable between a retracted position and an extended position. The probe may comprise a hook defined by one or more arcuate tines, wherein the concavity of the hook is configured to receive a target anatomical structure when in a target acquisition state. Additionally, or alternatively, a medical device may comprise a handle having first and second manually operated controls—and any other component—as described above.
The medical device and/or apparatuses described herein may also comprise a surgical tool, and in some embodiments, a surgical tool for use when performing carpal tunnel release surgery.
Referring now to
As illustrated in
Referring now to
As illustrated in
In one or more embodiments, activating the second trigger deploys blade 406 into an extended position, the blade 406 being positioned between (and associated with) two tines of the probe 406. With the blade 406 in an extended position and the probe 404 in a target acquisition state, as depicted in
It will be appreciated that the two triggers described above may be any manually operated control, including a multi-stage single trigger. For example, and with respect to the surgical tool depicted in
Referring now to
As depicted in
After TCL 420 is transected—whether entirely or partially—at least one of the probe and the blade, and in some embodiments both of the probe and the blade, are returned to an original position. For example, the probe is moved from a target acquisition state to a probing and/or retracted state and the blade is moved from an extended position to a retracted position. This may be accomplished by any mechanism known in the art. For example, returning the probe and/or blade to the original position may be accomplished by releasing and/or lifting one or more triggers operably connected to the probe and/or the blade. The surgical tool may then be withdrawn from the surgical site via the entry point.
While the foregoing has focused primarily on apparatuses having a body with a pivotally attached probe, it should be appreciated that in some embodiments, the body of the apparatus is structurally contiguous with the probe. Illustratively, the probe may be defined as the distal portion of the body, the probe having a fixed angle with respect to the remainder of the body. In such an embodiment, the probe, itself, is not deployable even though the blade may still be configured to move between retracted and extended positions.
For example,
The apparatus depicted in
With continued reference to
As shown in
Referring now to
With the blade 506 in an extended position and the probe 504 in a target acquisition state, as depicted in
Referring now to
As depicted in
After TCL 520 is transected—whether entirely or partially—the blade is returned to an original position. For example, the blade is moved from an extended position to a retracted position. This may be accomplished by any mechanism known in the art. For example, returning the blade to the original position may be accomplished by releasing and/or lifting one or more triggers operably connected to the blade. The surgical tool may then be withdrawn from the surgical site via the entry point.
Attention is now directed to
In a retracted state as depicted in
Referring now to
To facilitate movement of the probe 604 between the retracted state (
Referring now to
To facilitate movement of the blade 606 between the retracted state (
In some embodiments, the actuator 620 may be movable connected to the blade 606 so as to enable relative pivoting or rotational movement therebetween. In some embodiments, as shown in the Figures, an edge 624 of the blade 606 opposite the cutting edge 610 can rest on or otherwise interact with a pivot pin 614 about which the probe 604 pivots. The interaction between the edge 624 and the pivot pin 614 can guide the pivoting movement of the blade 606 as the blade 606 moves between the retracted and extended positions.
In some embodiments, such as that shown in
Referring now to
In addition to the probe 604 discussed above, the apparatus 600 may also include one or more additional features to facilitate the location of a target tissue. For instance, as shown in
Attention is now directed to
As shown in
In some embodiments, the body 654 of the adaptor 650 and the opening 652 in the handle 652 may have corresponding or mating alignment features to ensure that the adaptor 650 (particularly the body 654 thereof) is secured to the handle 642 in a predetermined or desired orientation. For instance, the opening 652 and the body 654 may have corresponding shapes that only allow the body 654 to be inserted into the opening 652 in a predetermined or desired orientation. In other embodiments, the opening 652 and the body 654 may have a mating key and keyway that only allow the body 654 to be inserted into the opening 652 in a predetermined or desired orientation. In some embodiments, after the adaptor 650 is be connected to the handle 642 in the predetermined or desired orientation, the orientation of the adaptor 650 may be selectively adjusted. For instance, upon loosening of the set screw 658, the adaptor 650 may be rotated (e.g., about an axis thereof) to change the orientation of the adaptor 650 from the predetermined or desired orientation to a second predetermined or desired orientation. Thereafter, the set screw 658 may be tightened to secure the adaptor 650 in the second predetermined or desired orientation.
The adaptor 650 also includes a thumb wheel 660 rotatably mounted on the body 654. Additionally, as shown in
The body 654 and the thumb wheel 660 include internal surfaces that cooperate to form the channel 662. The internal surfaces of the body 654 and thumb wheel 660 include corresponding slots 664, 666, respectively. While the illustrated embodiment includes multiple slots 664, 666 circumferentially disposed around the channel 662, other embodiments may include a single slot 664 and a single slot 666. In still other embodiments, the number of slots 664, 666 may not be the same as one another. For instance, the body 654 may have a single slot 664 and the thumb wheel 666 may include more than one slot 666. In any event, at least one slot 666 may be selectively aligned with at least one slot 664 (e.g., via relative rotation between the body 654 and the thumb wheel 660.
In the illustrated embodiment, the slots 666 have open proximal and distal ends. In contrast, the slots 664 have open distal ends and closed proximal ends. The slots 664, 666 are configured to receive one or more pins 668 on the apparatus 600. More specifically, the apparatus 600 includes a collar 670 from which the one or more pins 668 extend radially. The collar 670 is sized and configured to be received at least partially into the distal end of the channel 652. Prior to inserting the collar 670 into the channel 652, the slots 664, 666 are aligned with one another (e.g., such that the open proximal ends of the slots 666 are aligned with the open distal ends of the slots 664). The slots 664, 666 can be aligned with one another by rotating the body 654 and/or the thumb wheel 660 relative to one another. Once the slots 664, 666 are aligned with one another, the one or more pins 668 are aligned with the open distal ends of the slots 666 and the collar 670 is inserted into the channel 652.
As the collar 670 is inserted into the channel 652, the one or more pins 668 pass through the slots 666 and into the slots 664. The closed proximal ends of the slots 664 limits how far the collar 670 can be inserted into the channel 670. Inserting the pins 668 into the slots 664, 666 can ensure that the apparatus 600 is connected to the adaptor 650 is a predetermined or desired orientation. For instance, the slots 664, 666 may be disposed around the channel 652 such that the collar 670 may only be inserted into the channel 652 in one orientation. The predetermined or desired orientation may be an orientation about a longitudinal axis of the apparatus 600. As a result, the apparatus 600 may be secured to the adaptor 650 so that the probe 604 and blade 606 are extendable from the elongate member 602 is a particular direction relative to the handle 642.
The apparatus 600 and the adaptor 650 may be selectively secured together via a threaded connection. For instance, the interior surface of the channel 652 may include threads 672 and the exterior surface of the collar 670 may include exterior threads 674. Once the collar 670 is inserted into the channel 652 far enough that the pins 668 are disposed in the slots 664, the thumb wheel 660 may be rotated relative to the collar 670 so as to engage the threads 672, 674. Rotation of the thumb wheel 660 and engagement of the threads 672, 674 may draw the apparatus 600 and the adaptor 650 closer together. Additionally, the rotation of the thumb wheel 660 may misalign the slots 664, 666 such that the pins 668 are secured within the slots 664, which secures the apparatus 600 and the adaptor 650 together.
The apparatus 600 may be disconnection from the adaptor 650 in the reverse process described above. For instance, the thumb wheel 660 may be rotated to disengage the threads 672 from the threads 674. Additionally, the thumb wheel 660 may be rotated to align the slots 666 with the slots 664. When the threads 672, 674 disengages and the slots 664, 666 aligned with one another, the collar 670 may be withdrawn from the adaptor 650. As the collar 670 is withdrawn from the adaptor 650, the one or more pins 668 may pass through the slots 664, 666 and out of the distal open ends of the slots 666.
With the apparatus 600 disconnected from the adaptor 650, the blade 606 and the associated actuator 622 may be removed from the elongate member 602. For instance, the blade 606 and the actuator 622 may be withdrawn from the elongate member 602 through an open proximal end in the elongate member 602. The remainder of the apparatus 600 may be cleaned and sterilized for subsequent uses. The blade 606 and the actuator 622 may be replaced with a new blade and actuator. Thus, part of the apparatus 600 may be reusable (e.g., configured for multiple uses, cleanable/sterilizable) and part of the apparatus may be designed for single use and/or replaceable.
Attention is now directed to
Attention is now directed to
Using any of the surgical tools described above in carpal tunnel release surgery provides many benefits over the currently available tools and procedures. For example, the surgical tool can be used in a minimally invasive surgical procedure that only requires a single entry point, whether introduced via an incision or via a percutaneous procedure. This translates into less bleeding, a lower chance of infection, less pain, and less scarring, which typically results in faster patient recovery times when compared to open surgical techniques or even other minimally invasive surgical techniques that require two portals for performing the surgery. Additionally, use of the disclosed surgical tool in carpal tunnel release surgery does not require surgical robotics that are costly and could malfunction during surgery and potentially affect surgical outcome. Further, the disclosed surgical tool does not require—though it may often be used with—an accompanying endo scope or other image-guided surgical instruments (e.g., ultrasound systems, computed tomography scanners, magnetic resonance imaging scanners, etc.). Overall, the disclosed surgical device results in a safer and more simplistic approach to performing carpal tunnel release surgery.
Many of the foregoing advantages are equally relevant to any of the handheld apparatuses disclosed herein. Additional advantages—whether in the particular context of carpal tunnel release surgery or generally relevant—include the ability to advance a probe at or near a target location without damaging surrounding structures. For example, the blade may be in a retracted position during the probing stage whereby the cutting edge is safely occluded, thereby preventing any accidental cutting or snagging of unintended targets.
Also, the probe, in some embodiments, is arcuate such that the probing surface (e.g., the side opposite the target interaction surface) has a convex contour that allows the probe to more naturally and/or smoothly advance through an environment without snagging and/or tearing any surrounding structures. In a target acquisition state of the probe, the convex contour may additionally be configured to purposefully engage a target. Even then, however, some embodiments of the present disclosure provide that when the probe is in the target acquisition state, the blade is in a retracted position, preventing any unintentional cutting from occurring. Upon activation (e.g., extension or protrusion) of the blade, the acquired target may be cut. In this way, the handheld apparatuses of the present disclosure provide a device that enables target specific cutting.
In one or more embodiments of the present disclosure, the probe and/or blade of the handheld apparatus are operably connected to one or more manually operated controls on an associated handle. These manually operated controls activate the probe and may, in some embodiments, independently control the positioning of the blade (e.g., operating the blade between a retracted or extended state). Certain advantages of this include the ability to extend the probe and/or blade at a specific time and/or place followed by retraction of the probe and/or blade so that when the apparatus is withdrawn, no other structures are cut, snagged, or otherwise unintentionally damaged. When used in a surgical setting, this translates into a surgical tool that may be introduced at a distant site and safely advanced to a target site where a target anatomic structure is acquired and severed by a selectively extended surgical blade. The surgical blade and/or probe may then be retracted at the target site followed by being safely withdrawn without further or unintentional interference.
In some embodiments, a handheld apparatus for probing and cutting comprises (i) an elongate member comprising a first end and a second end, (ii) a probe disposed at the first end of the elongate member and comprising a target interaction surface, the probe being fixed at an angle respective to the elongate body, and (iii) a blade associated with the first end of the elongate member and comprising a cutting edge, the blade being selectively movable between a retracted position and an extended position.
In some embodiments of the foregoing handheld apparatus, the cutting edge of the blade is obscured at least partially by the elongate member when the blade is in the retracted position.
In some additional, or alternative, embodiments, the probe further defines a recess configured to receive at least a portion of the blade when the blade is in the extended position.
In some additional, or alternative, embodiments, the handheld apparatus further comprises a handle associated with the second end of the elongate member that is operably connected to the blade by a manually operated control, the manually operated control being configured to extend the blade from a retracted state retracted state when engaged. The manually operated control can, in some embodiments, be selected from the group consisting of: a dial, a switch, a slider, a button, a lever, a trigger, and combinations thereof and can additionally, or alternatively, be configured to cause the blade to pivot towards the retracted state when the first trigger is disengaged.
In some embodiments, a medical device for probing and cutting, comprises (i) an elongate member comprising a first end and a second end, (ii) a probe associated with the first end of the elongate member, (iii) a blade associated with the probe and comprising a cutting edge, the blade being selectively movable between a retracted position and an extended position, and (iv) a handle associated with the second end of the elongate member, the handle operably connected to the blade.
In some embodiments of the foregoing medical device for probing and cutting, the probe comprises a hook defined by one or more arcuate tines and having a recess therein. In some embodiments, the blade is disposed within the recess.
In some embodiments, the probe is associated with the elongate member at a fixed angle. It may be any angle disclosed herein, including, for example, the terminal tip of the probe being disposed at a fixed angle between about 45°-60° relative to the elongate member.
Additionally, or alternatively, the handle can further comprise a manually operated control selected from the group consisting of: a dial, a switch, a slider, a button, a lever, a trigger, and combinations thereof, the manually operated control being operably connected to the blade such that engagement of the manually operated control selectively moves the blade between the retracted position and the extended position.
Any of the foregoing handheld devices, medical tools, and/or surgical tools can be sized and shaped for use in a minimally invasive carpal tunnel surgery.
To assist in understanding the scope and content of the foregoing written description and appended claims, a select few terms are defined directly below.
The term “blade” refers to any sharp instrument known in the art that is configured to cut and can be made of any suitable material, particularly those materials known and used in the art of surgery (e.g., stainless steel, tempered steel, high carbon steel, titanium, ceramic, etc.). A blade, as used herein, includes any appropriately sized and shaped surgical knife, scalpel, lancet, or other sharp surgical instrument suited to the methods described herein. The blades disclosed herein may be re-useable or disposable and may be interchangeable.
For the purposes of this description, the term “introduce” is intended to include any of its common denotative meanings, and particularly in the context of this description, the term “introduce” may refer to inserting an object (e.g., medicine, surgical tool, etc.) into the body of a patient.
The term “introducer sheath” generally refers to a tube that can be introduced into the body and through which medicines, surgical tools, and/or other medically relevant material may be delivered into the body. As used herein, an introducer sheath may be flexible or rigid and may be of any length and gauge as known and used by those having skill in the art, as appropriate. An introducer sheath may additionally comprise a length and gauge sufficient to introduce the disclosed apparatus comprising a deployable probe and blade inside the body, regardless of whether the length and gauge of said introducer sheath is known and used by those having skill in the art. When referenced, an introducer sheath is understood to include cannulas, catheters, and any similar device falling within the scope of this definition. An introducer sheath may include one or more elements as known in the art, including without limitation, a guidewire, a dilator, a sheath, a side tube (with or without a stop cock), a valve, a seal, and/or a locking mechanism. An introducer sheath may be used in a vascular procedure as known in the art wherein the introducer sheath is disposed within the lumen of a blood vessel. Additionally, or alternatively, an introducer sheath may be used in a percutaneous procedure where the introducer sheath is disposed within the body of a patient but outside of the vasculature. Additionally, or alternatively, an introducer sheath may be disposed within the body through an open surgical procedure as known in the art (e.g., cutting any of the epidermis, dermis, subcutaneous tissue, muscle, etc. with a scalpel followed by introduction of the introducer sheath into the body through the incision made by the scalpel).
For the purposes of this description, the term “minimally invasive surgery” as used herein refers to surgical techniques that limit the size of incisions needed and in so doing lessens wound healing time, associated pain, and risk of infection as compared to open surgery techniques as known in the art. This term is meant to include, for example, robotic assisted surgeries and any of the many varieties of endoscopic surgeries known in the art. This term is also meant to include colloquial equivalents such as “band-aid surgery” and “keyhole surgery.”
The term “patient” generally refers to any animal under the care of a physician, as that term is defined herein, with particular reference to humans under the care of a surgeon or other relevant medical professional.
The term “physician” as used herein generally refers to a medical doctor, particularly a surgeon. This term may, when contextually appropriate, include any medical professional, including any licensed medical professional, such as a physician's assistant, a nurse, a genetics counselor, a veterinarian, etc.
The terms “position” and “state” as used with reference to a blade and probe, respectively, are made with respect to various stages or conformations. For example, a blade may be in a retracted position or an extended position. A probe may be in a retracted state, a probing state, or a target acquisition state.
Throughout the disclosure, the probe may be referenced in one or more probe states. For example, the probe may be referenced in a retracted state, a probing state, or a target acquisition state. For the purposes of this disclosure, a retracted state includes any initial state of a probe where the probe is drawn substantially toward the elongate member or is otherwise undeployed from an elongate member (see, for example,
For the purposes of this disclosure, a target acquisition state includes any fully extended or fully deployed probe state (see, for example,
For the purposes of this disclosure, a probing state includes any state between the retracted state and the target acquisition state. In some embodiments, the probing state includes those intermediate states between a retracted state and a target acquisition state where the probe may be used to probe or identify a potential target. A probe in a probing state may be selectively movable between a retracted state and a target acquisition state. In some embodiments, a probing state may be interchangeable with a retracted state. For example, a probe in a retracted state may be used to search for one or more potential targets. In such an embodiment, the probe may not have substantially moved away from the retracted state but may nonetheless be considered to be in a probing state and/or a retracted state. Similarly, a probe may be in a probing state when it is released from a retracted state and is rotated or otherwise moved to identify a target. As the probe rotates or moves away from the retracted state, the probe may identify a target at a given probe position, and without additional rotation or movement from the given probe position, the probe may transition from a probing state to a target acquisition state upon identification of a desired target. Thus, as used herein, a target acquisition state describes those probe states where the probe positively acquires or is otherwise associated with a target, and a probing state can be any probe position between (or outside) the retracted state and the target acquisition state.
Accordingly, in some embodiments, the probe may be in a retracted state when the probe is substantially parallel to an elongate member. If, as provided by some embodiments described herein, the probe is rotated from a retracted state to a target acquisition state, the retracted state can be considered a rotational starting point—or 0° of rotation. In some embodiments, the target acquisition state is any of a 15°, 30°, 45°, 60°, 75°, 90°, 105°, 120°, 135°, 150°, 165°, or 180° rotation (in either a clockwise or counterclockwise direction) from the retracted state, and the probing state includes any intermediate rotation between (and sometimes including) the retracted state and the target acquisition state.
For example, in an embodiment where the target acquisition state is 115° clockwise rotation from the retracted state (e.g., 0°), the probing state may be any angular rotation between 0° and 115°. In some embodiments, the probing state includes all possible points within an available 360° of rotation from the retracted position, and the target acquisition state is defined as the point (e.g., the state) where the probe acquires a target. As adapted from the previous example, the probing state may include all available rotational states of a given probe that can rotate 180° from the retracted state, and upon acquiring a target at, for example, 115° from the retracted state, the probe can be considered to be in a target acquisition state.
In some embodiments, the target acquisition state can be a given state within a range of states. For example, a desired target may be acquired by the probe within a range of states, which may vary between environments, but which nonetheless fall within a defined (or reasonably defined) range of states. As a more particular example, the desired target may be the TCL, which may be acquired by a probe in one or more states between 30° and 180°, or between 45° and 165°, or between 60° and 135°. The probe may, in a probing state, probe for the TCL between any of the foregoing ranges until the TCL is acquired. The state in which the TCL was acquired is the target acquisition state.
In one or more embodiments, the target acquisition state may include the fully extended (or fully rotated) state of the probe away from the retracted state, which in some embodiments may include a target acquisition state that falls within any of the rotational ranges or rotation states described above. In such embodiments, the probing state may be defined as any intermediate state between the retracted state and the target acquisition state.
Throughout the disclosure, the blade may be referenced in one or more blade positions. For example, the blade may be referenced in a retracted position or an extended position. For the purposes of this disclosure, the blade is selectively movable between a retracted position and an extended position.
A retracted position includes any initial position of a blade where the blade is drawn substantially toward or within the elongate member or is otherwise undeployed. In some embodiments, a blade is nestled within a recess formed within the elongate member when in a retracted position.
An extended blade position includes any position of a blade that is not a retracted position. The extended position of a blade, as used herein, includes any partially or fully extended blade position.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present disclosure pertains. The present disclosure may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. While certain embodiments and details have been included herein and in the attached disclosure for purposes of illustrating embodiments of the present disclosure, it will be apparent to those skilled in the art that various changes in the methods, products, devices, and apparatus disclosed herein may be made without departing from the scope of the disclosure or of the invention, which is defined in the appended claims. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
Taylor, Roy M., Gowski, William F.
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